Abstract: A method of fabricating a ferroelectric capacitor is disclosed. The method comprises the decreases a reduction in a bottom electrode material during formation of the ferroelectric dielectric portion of the capacitor. In the above manner, a fatigue resistance of the ferroelectric capacitor is increased substantially.

Abstract: A method for controlling the crystallographic texture of thin films with anisotropic ferroelectric polarization or permittivity by means of ion bombardment resulting in a texture with higher ferroelectric polarization or permittivity which is normally energetically disfavored.

Abstract: An integrated circuit device includes a two-dimensional array of ferroelectric memory cells in which plate lines within the array are grouped. The grouping of plate lines accommodates the use of larger plate line drivers, such as CMOS driver inverters. Each plate line group may include some but not all of the rows of memory cells and some but not all of the columns of memory cells within the array.

Abstract: One aspect of the invention relates to a method of manufacturing a semiconductor device in which an alignment mark is formed by a plurality of adjacent filled trenches. A processing tool detects the trenches as though they were a single filled trench of larger dimension. When the trenches are metal filled, the metal is more easily protected from oxidation than when the metal is formed into a single large trench, an effect that is pronounced when the trenches are filled with tungsten. Another aspect of the invention relates to an alignment mark formed by a plurality of tungsten filled trenches. The alignment mark can be used to align the pattern for an FeRAM capacitor stack to underlying tungsten contacts.

Abstract: The present invention is directed to a method of forming an FeRAM integrated circuit, which includes performing a capacitor stack etch to define the FeRAM capacitor. The method comprises etching a PZT ferroelectric layer with a high temperature BCl3 etch which provides substantial selectivity with respect to the hard mask. Alternatively, the PZT ferroelectric layer is etch using a low temperature fluorine component etch chemistry such as CHF3 to provide a non-vertical PZT sidewall profile. Such a profile prevents conductive material associated with a subsequent bottom electrode layer etch from depositing on the PZT sidewall, thereby preventing leakage or a “shorting out” of the resulting FeRAM capacitor.

Abstract: An integrated circuit device includes a two-dimensional array of ferroelectric memory cells in which plate lines within the array are grouped. The grouping of plate lines accommodates the use of larger plate line drivers, such as CMOS driver inverters. Each plate line group may include some but not all of the rows of memory cells and some but not all of the columns of memory cells within the array.

Abstract: A method of fabricating a ferroelectric capacitor is disclosed. The method comprises the decreases a reduction in a bottom electrode material during formation of the ferroelectric dielectric portion of the capacitor. In the above manner, a fatigue resistance of the ferroelectric capacitor is increased substantially.

Abstract: A method of fabricating a ferroelectric capacitor is disclosed. The method comprises the patterning of a top electrode layer and a dielectric layer to form a capacitor stack structure having sidewalls associated therewith. Prior to patterning the bottom electrode layer, a protective film is formed on the sidewalls of the capacitor stack structure in order to protect the dielectric material from conductive contaminants associated with a subsequent patterning of the bottom electrode layer.

Abstract: The present invention is directed to a method of forming an FeRAM integrated circuit, which includes performing a capacitor stack etch to define the FeRAM capacitor. The method comprises etching a PZT ferroelectric layer with a high temperature BCl3 etch which provides substantial selectivity with respect to the hard mask. Alternatively, the PZT ferroelectric layer is etch using a low temperature fluorine component etch chemistry such as CHF3 to provide a non-vertical PZT sidewall profile. Such a profile prevents conductive material associated with a subsequent bottom electrode layer etch from depositing on the PZT sidewall, thereby preventing leakage or a “shorting out” of the resulting FeRAM capacitor.

Abstract: The present invention is directed to a method of forming an FeRAM integrated circuit, which includes performing a capacitor stack etch to define the FeRAM capacitor. The method comprises etching a PZT ferroelectric layer with a high temperature BCl3 etch which provides substantial selectivity with respect to the hard mask. Alternatively, the PZT ferroelectric layer is etch using a low temperature fluorine component etch chemistry such as CHF3 to provide a non-vertical PZT sidewall profile. Such a profile prevents conductive material associated with a subsequent bottom electrode layer etch from depositing on the PZT sidewall, thereby preventing leakage or a “shorting out” of the resulting FeRAM capacitor.

Abstract: A method of fabricating a ferroelectric capacitor is disclosed. The method comprises decreasing a reduction in a bottom electrode material during formation of the ferroelectric dielectric portion of the capacitor. The method comprises forming an oxygen doped iridium layer and forming a ferroelectric dielectric layer thereover. During the formation of the ferroelectric, the oxygen doped iridium layer converts to an iridium oxide layer.

Abstract: A preferred embodiment of this invention comprises a conductive lightly donor doped perovskite layer (e.g. lightly La doped BST 34), and a high-dielectric-constant material layer (e.g. undoped BST 36) overlaying the conductive lightly donor doped perovskite layer. The conductive lightly donor doped perovskite layer provides a substantially chemically and structurally stable electrical connection to the high-dielectric-constant material layer. A lightly donor doped perovskite generally has much less resistance than undoped, acceptor doped, or heavily donor doped HDC materials. The amount of donor doping to make the material conductive (or resistive) is normally dependent on the process conditions (e.g. temperature, atmosphere, grain size, film thickness and composition). This resistivity may be further decreased if the perovskite is exposed to reducing conditions.

Abstract: The present invention is directed to a method of forming an FeRAM integrated circuit, which includes forming a TiAlON bottom electrode diffusion barrier layer prior to formation of the bottom electrode layer in an FeRAM capacitor stack. Subsequently, when performing the capacitor stack etch, the portion of the TiAlON diffusion barrier layer not covered by the FeRAM capacitor stack is etched substantially anisotropically due to the oxygen within the TiAlON diffusion barrier layer substantially preventing a lateral etching thereof. In the above manner, an undercut of the TiAlON diffusion barrier layer under the FeRAM capacitor stack is prevented. In another aspect of the invention, a method of forming an FeRAM capacitor comprises forming a multi-layer bottom electrode diffusion barrier layer. Such formation comprises forming a TiN layer over the interlayer dielectric layer and the conductive contact and forming a diffusion barrier layer thereover.

Abstract: The present invention is directed to a method of forming an FeRAM integrated circuit, which includes forming a sidewall diffusion barrier prior to etching the bottom electrode diffusion barrier layer. The sidewall diffusion barrier layer is then etched prior to the bottom electrode diffusion barrier layer. In patterning an AlOx sidewall diffusion barrier layer prior to etching the underlying bottom electrode diffusion barrier layer, the etch chemistry comprises BCl3+Ar. The BCl3 is effective in etching the AlOx with a good selectivity to the underlying nitride hard mask on top of the capacitor stack (e.g., TiAlN) and nitride bottom electrode diffusion barrier (e.g., TiAlON with small oxygen content) between the neighboring capacitor stacks. The Ar may be added to the etch chemistry because the resulting surface (of a top portion of the hard mask and the bottom electrode diffusion barrier) is smoother.

Abstract: The present invention is directed to a method of forming an FeRAM integrated circuit, which includes forming a multi-layer hard mask. The multi-layer hard mask comprises a hard masking layer overlying an etch stop layer. The etch stop layer is substantially more selective than the overlying masking layer with respect to an etch employed to remove the bottom electrode diffusion barrier layer. Therefore during an etch of the capacitor stack, an etch of the bottom electrode diffusion barrier layer results in a substantially complete removal of the hard masking layer. However, due to the substantial selectivity (e.g., 10:1 or more) of the etch stop layer with respect to the overlying masking layer, the etch stop layer completely protects the underlying top electrode, thereby preventing exposure thereof.

Abstract: The present invention is directed to a method of forming an FeRAM integrated circuit, which includes evaluating the capacitor stack to determine the efficacy of the sidewall diffusion barrier layer deposition. When evaluating the capacitor stack after etching a masking layer portion of the hard mask, if “ears” are seen on top of the stack, the sidewall diffusion barrier layer is sufficiently thick to provide an adequate sidewall barrier. Evaluation may be performed using a standard or tilt scanning electron microscope, for example.

Abstract: A method of fabricating a ferroelectric capacitor is disclosed. The method comprises the decreases a reduction in a bottom electrode material during formation of the ferroelectric dielectric portion of the capacitor. In the above manner, a fatigue resistance of the ferroelectric capacitor is increased substantially.

Abstract: A method of fabricating a ferroelectric capacitor is disclosed. The method comprises the patterning of a top electrode layer and a dielectric layer to form a capacitor stack structure having sidewalls associated therewith. Prior to patterning the bottom electrode layer, a protective film is formed on the sidewalls of the capacitor stack structure in order to protect the dielectric material from conductive contaminants associated with a subsequent patterning of the bottom electrode layer.

Abstract: A method of fabricating a ferroelectric capacitor is disclosed. The method comprises the decreases a reduction in a bottom electrode material during formation of the ferroelectric dielectric portion of the capacitor. In the above manner, a fatigue resistance of the ferroelectric capacitor is increased substantially.

Abstract: A method of fabricating a ferroelectric capacitor is disclosed. The method comprises the decreases a reduction in a bottom electrode material during formation of the ferroelectric dielectric portion of the capacitor. In the above manner, a fatigue resistance of the ferroelectric capacitor is increased substantially.